Sage Journals: Discover world-class research

Abstract

Turbine generator (TG) buildings in thermal power plants require chilled water air conditioning systems (CWAS) to control the temperature and humidity of heat dissipated rooms, which are energy-intensive and non-eco-friendly. As an alternative, a novel refrigerant-free 100% fresh air (FA)-based hybrid liquid desiccant air conditioning system (HLDAS) is proposed and presented the methodology to design it for a case study of TG building of 2X660 MW power plant in the most humid climate. The cooling and heating requirements for HLDAS are met with a cooling tower and potential waste heat from the plant. To assess the saving potential of the proposed system, annual energy consumption for the HLDAS, 10% FA-based CWAS (CWAS-1) and 100% FA-based CWAS (CWAS-2) are quantified and compared. The results revealed that HLDAS consume 55% and 31% of CWAS-1 and CWAS-2 power consumption, respectively. Low-grade potential waste heat from the plant is estimated and found to be sufficient for solution regeneration. The proposed system is extremely energy efficient for 100% FA applications where low-grade waste heat is available. In addition to this, since there are no ODP gases associated with the proposed system, the proposed HLDAS is recommendable in view of environmentally friendly technology and indoor air quality (since it is a 100% FA-based system). This work will support HVAC engineers and researchers in designing the LDAS for a given air conditioning application.

Keywords

Chiller cooling tower LiBr hot and humid climate waste heat power consumption

Get full access to this article

View all access options for this article.

References

Mohammad

Bin Mat

Sulaiman

, et al. Survey of liquid desiccant dehumidification system based on integrated vapor compression technology for building applications. Energy Build 2013; 62: 1–14.

Chen

Yin

Zhang

. Performance analysis of a hybrid air-conditioning system dehumidified by liquid desiccant with low temperature and low concentration. Energy Build 2014; 77: 91–102.

Shan

Yin

Zhang

. Study on performance of a novel energy-efficient heat pump system using liquid desiccant. Appl Energy 2018; 219: 325–337.

Lee

Jeong

. Design of heat pump-driven liquid desiccant air conditioning systems for residential building. Appl Therm Eng 2020 183: 116207.

Abdel-Salam

Simonson

. Optimal design, sizing and operation of heat-pump liquid desiccant air conditioning systems. Sci Technol Built Environ 2020; 26: 161–176.

Cui

Sun

, et al. Operating characteristics and performance evaluation of carbon dioxide heat pump driven liquid desiccant dehumidification systems: a comparative study. Energy Convers Manag 2022; 254: 115298.

Gurubalan

Maiya

Tiwari

. Performance characterization of a novel membrane-based liquid desiccant air conditioning system. Int J Refrig 2020; 120: 445–459.

Guan

Liu

Zhang

. Analytical solutions for the optimal cooling and heating source temperatures in liquid desiccant air-conditioning system based on exergy analysis. Energy 2020; 203: 117860.

Jeong

J-W

. Energy performance of liquid desiccant and evaporative cooling-assisted 100% outdoor air systems under various climatic conditions. Energies 2018; 11: 1377.

10.

Park

Kim

Yoon

, et al. Experimental analysis of dehumidification performance of an evaporative cooling-assisted internally cooled liquid desiccant dehumidifier. Appl Energy 2019; 235: 177–185.

11.

Dong

Jeong

. Energy benefits of organic Rankine cycle in a liquid desiccant and evaporative cooling-assisted air conditioning system. Renew Energy 2020; 147: 2358–2373.

12.

Gao

Cheng

Jiang

, et al. Experimental investigation on integrated liquid desiccant - indirect evaporative air cooling system utilizing the Maisotesenko - cycle. Appl Therm Eng 2015; 88: 288–296.

13.

Kim

Park

Jeong

. Energy saving potential of liquid desiccant in evaporative-cooling-assisted 100% outdoor air system. Energy 2013; 59: 726–736.

14.

Kim

Yoon

Kim

, et al. Retrofit of a liquid desiccant and evaporative cooling-assisted 100% outdoor air system for enhancing energy saving potential. Appl Therm Eng 2016; 96: 441–453.

15.

Ham

Lee

Jeong

. Operating energy savings in a liquid desiccant and dew point evaporative cooling-assisted 100% outdoor air system. Energy Build 2016; 116: 535 552.

16.

Shin

J-H

Park

J-Y

M-S

, et al. Impact of heat pump-driven liquid desiccant dehumidification on the energy performance of an evaporative cooling-assisted air conditioning system. Energies 2018; 11: 45.

17.

Ghosh

Bhattacharya

. A solar regenerated liquid desiccant evaporative cooling system for office building application in hot and humid climate. Therm Sci Eng Prog 2020 22: 100804.

18.

Katejanekarn

Chirarattananon

Kumar

. An experimental study of a solar-regenerated liquid desiccant ventilation pre-conditioning system. Sol Energy 2009; 83: 920–933.

19.

Huang

. Parameter analysis and optimization of the energy and economic performance of solar-assisted liquid desiccant cooling system under different climate conditions. Energy Convers Manag 2015; 106: 1387–1395.

20.

Mohamed

ASA

Ahmed

Hassan

AAM

, et al. Performance evaluation of gauze packing for liquid desiccant dehumidification system. Case stud Therm Eng 2016; 8: 260–276.

21.

Cai

, et al. Experimental investigations on heat and mass transfer performances of a liquid desiccant cooling and dehumidification system. Appl Energy 2018; 220: 164–175.

22.

Wang

Xiao

Niu

, et al. Experimental study of dynamic characteristics of liquid desiccant dehumidification processes. Sci Technol Built Environ 2017; 23: 4731.

23.

Wang

Zhang

. Investigation on the coupled heat and mass transfer process between extremely high humidity air and liquid desiccant in the counter-flow adiabatic packed tower. Int J Heat Mass Transf 2017; 110: 898–907.

24.

Ghadiri Moghaddam

Namvar

, et al. Analytical model based performance evaluation, sizing and coupling flow optimization of liquid desiccant run-around membrane energy exchanger systems. Energy Build 2013; 62: 248–257.

25.

Kumar Reddy

Balasubramanian

Chandramohan

. Influence of potential liquid desiccants on solution cooling, heating, and pumping loads of membrane-based liquid desiccant air conditioning system: an analytical study. Sci Technol Built Environ 2019; 25: 753–766.

26.

Reddy

YSK

Balasubramanian

. Thermal energy analysis on liquid desiccant air conditioning system at different desiccant solution parameters. J Process Mech Eng 2019; 233: 1052–1065.

27.

Zhang

L-Z

. An analytical solution to heat and mass transfer in hollow fiber membrane contactors for liquid desiccant air dehumidification. J Heat Transfer 2011; 133: 092001.

28.

Incropera

F.P.

Bergman

T.L.

Lavine

A.S.

, D.P., et al. Fundamentals of Heat and Mass Transfer, 2011. 10.1073/pnas.0703993104.

29.

Pátek

Klomfar

. A computationally effective formulation of the thermodynamic properties of LiBr-H₂O solutions from 273 to 500 K over full composition range. Int J Refrig 2006; 29: 566–578.

30.

Reddy

Balasubramanian

Chandramohan

. Study on desiccant solution control strategies for efficient liquid desiccant air conditioning system control performance. Sci Technol Built Environ 2019; 25: 322–335.

31.

Forman

Muritala

Pardemann

, et al. Estimating the global waste heat potential. Renew Sustain Energy Rev 2016; 57: 1568–1579.

Design and energy analysis of 100% fresh air based hybrid liquid desiccant air conditioning system – A case study of a thermal power plant TG building

Abstract

Keywords

Get full access to this article

References